Multilayered printed wiring board and method for manufacturing the same

ABSTRACT

A multilayered printed wiring board includes a flexible wiring board with wiring layers on both main surfaces thereof; a rigid wiring board with wiring layers on both main surfaces thereof and formed opposite to the flexible wiring board under the condition that an area of the main surface of the rigid wiring board is smaller than an area of the main surface of the flexible wiring board; and an electric/electronic component embedded in the rigid wiring board.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is based upon and claims the benefit of priority fromthe prior Japanese Patent Application No. 2006-205640 filed on Jul. 28,2006; the entire contents which are incorporated herein by reference.

BACKGROUND

1. Field of the Invention

The present invention relates to a multilayered printed wiring board,e.g., which is employed as a module board in a portable device and amethod for manufacturing the multilayered printed wiring board.

2. Description of the Related Art

Recently, the downsizing and the weight saving for a portable devicesuch as a cellular phone are developed and moreover, the performance ofthe portable device is developed. In addition, some instruments arecombined with one another in the portable device. In this case, amultilayered printed wiring board is employed as the module board in theportable device. In view of the above-described requirements forportable device, it is desired to downsize, thin and grow in density themultilayered printed wiring board. In addition, some hardness andflexibility are required for the multilayered printed wiring board. Forexample, the hardness is required to realize the mechanical strength ofthe multilayered printed wiring board. The flexibility is required tohouse the multilayered printed wiring board in a narrow case under thebending condition.

Conventionally, a rigid-flexible wiring board is employed so as tosatisfy the hardness and the flexibility. The applicant proposed a newtype rigid-flexible wiring board in Reference 1 so as to develop thematerial yield. In Reference 1, the rigid wiring board and the flexiblewiring board are laminated via a semi-hardened prepreg and pressed underthe heating condition. In this case, the wiring pattern of the rigidwiring board is electrically connected with the wiring pattern of theflexible wiring board via interlayer connection conductors such asconductive bumps through the prepreg. In Patent Reference 1, theintended rigid-flexible wiring board is fabricated through theabove-described manufacturing process.

[Reference 1] JP-A No. 2005-322878 (KOKAI)

In Reference 1, the intended rigid-flexible wiring board can be easilyfabricated from the rigid wiring board and the flexible wiring board athigher material yield, but can not satisfy the downsizing of the boardbecause the number of electric/electronic component can not be reduced.

BRIEF SUMMARY OF THE INVENTION

In view of the above-described problems, it is an object to provide amultilayered printed wiring board wherein the number ofelectric/electronic component can be reduced so as to downsize the boarditself and the method for manufacturing the multilayered printed wiringboard.

In order to achieve the above object, an aspect of the present inventionrelates to a multilayered printed wiring board, including: a flexiblewiring board with wiring layers on both main surfaces thereof; a rigidwiring board with wiring layers on both main surfaces thereof and formedopposite to the flexible wiring board under the condition that an areaof the main surface of the rigid wiring board is smaller than an area ofthe main surface of the flexible wiring board; and anelectric/electronic component embedded in the rigid wiring board.

In an embodiment, the multilayered printed wiring board also includes:an insulating layer disposed between the flexible wiring board and therigid wiring board; and an interlayer connection conductor formed alongan axial direction thereof and disposed between the flexible wiringboard and the rigid wiring board through the insulating layer so as toelectrically connect the flexible wiring board and the rigid wiringboard via the wiring layers formed on the main surfaces of the flexiblewiring board and the rigid wiring board; wherein a diameter of theinterlayer connection conductor in the side of the rigid wiring board isset smaller than a diameter of the interlayer connection conductor inthe side of the flexible wiring board.

Another aspect of the present invention relates to a multilayeredprinted wiring board, including: a flexible wiring board with wiringlayers on both main surfaces thereof; a rigid wiring board with wiringlayers on both main surfaces thereof and formed opposite to the flexiblewiring board via an insulating layer; an interlayer connection conductordisposed through the insulating layer so as to electrically connect theflexible wiring board and the rigid wiring board under the conditionthat a forefront of the interlayer connection conductor is plasticallydeformed through the connection for the rigid wiring board and a bottomof the interlayer connection conductor is connected with a connectionland of the wiring layer of the flexible wiring board; and anelectric/electronic component embedded in the rigid wiring board.

Still another aspect of the present invention relates to a method formanufacturing a multilayered printed wiring board, comprising the stepsof: preparing a first rigid board and a second rigid board; mounting anelectric/electronic component on a main surface of the first rigidboard; forming a roll off to house the electric/electronic component atthe second rigid board; laminating the first rigid board and the secondrigid board so that the electric/electronic component can be inserted inthe roll off, thereby forming a rigid wiring board; and laminating therigid wiring board and a flexible wiring board via a prepreg to beconverted into an insulating layer so that the rigid wiring board can beelectrically connected with the flexible wiring board via an interlayerconnection conductor.

According to the aspects of the present invention, since theelectric/electronic component is embedded in the rigid wiring board, thethus obtained multilayered printed wiring board can be reduced in sizeeven though the number of electric/electronic component is not reduced.Since the multilayered printed wiring board can exhibit the hardness andthe flexibility, the multilayerd printed wiring board can be employed asthe module board so as to realize the downsized portable device.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

FIG. 1( a) is a top plan view showing the structure of a multilayeredprinted wiring board according to an embodiment of the presentinvention.

FIG. 1( b) is a bottom plan view showing the structure of a multilayeredprinted wiring board according to an embodiment of the presentinvention.

FIG. 2 is a cross sectional view showing the structure of themultilayered printed wiring board in FIG. 1, taken on line A-A.

FIG. 3 is a cross sectional view showing the structure of a multilayeredprinted wiring board modified from the one shown in FIG. 2.

FIG. 4 is a cross sectional view showing the structure of anothermultilayered printed wiring board modified from the one shown in FIG. 2.

FIG. 5 relates to cross sectional views schematically showing some stepsin a manufacturing method for the multilayered printed wiring board inFIG. 2.

FIG. 6 relates to cross sectional views schematically showing some stepsin a manufacturing method for the rigid wiring board of the multilayeredprinted wiring board in FIG. 2.

FIG. 7A relates to cross sectional views schematically showing somesteps in a manufacturing method for the rigid wiring board of themultilayered printed wiring board in FIG. 2.

FIG. 7B relates to cross sectional views schematically showing someother steps in a manufacturing method for the rigid wiring board of themultilayered printed wiring board in FIG. 2.

FIG. 8 relates to cross sectional views schematically showing some stillother steps in a manufacturing method for the rigid wiring board of themultilayered printed wiring board in FIG. 2.

FIG. 9 is a cross sectional view schematically showing a rigid wiringboard of the multilayered printed wiring board in FIG. 2.

FIG. 10 relates to cross sectional views schematically showing someother steps in a manufacturing method for the multilayered printedwiring board.

FIG. 11 relates to cross sectional views schematically showing somesteps in a manufacturing method for the flexible wiring board of themultilayered printed wiring board in FIG. 2.

FIG. 12 relates to cross sectional views schematically showing somesteps in a manufacturing method for the multilayered printed wiringboard in FIG. 2.

FIG. 13 relates to cross sectional views schematically showing somesteps in a manufacturing method for the multilayered printed wiringboard in FIG. 3.

FIG. 14 relates to a cross sectional view schematically showing a stepin a manufacturing method for the multilayered printed wiring board inFIG. 4.

FIG. 15 relates to a cross sectional view schematically showing anotherstep in a manufacturing method for the multilayered printed wiring boardin FIG. 4.

FIG. 16 relates to a cross sectional view schematically showing stillanother step in a manufacturing method for the multilayered printedwiring board in FIG. 4.

BEST MODE FOR IMPLEMENTING THE INVENTION

Hereinafter, the present invention will be described in detail withreference to the drawings. Like or corresponding components aredesignated by the same reference numerals throughout the drawings andthe explanation for like or corresponding components will be omitted.The embodiments and the drawings will be described for the convenienceof the understanding of the present invention so that the presentinvention is not limited to the embodiments and the drawings. Moreover,the drawings are schematically illustrated so that some components maybe different from real ones.

First of all, a multilayered printed wiring board according to thisembodiment will be described with reference to FIGS. 1 to 4. FIG. 1( a)is a top plan view showing the structure of the multilayered printedwiring board according to this embodiment. FIG. 1( b) is a bottom planview showing the structure of the multilayered printed wiring boardaccording to this embodiment. FIG. 2 is a cross sectional view showingthe structure of the multilayered printed wiring board in FIG. 1, takenon line A-A. FIG. 3 is a cross sectional view showing the structure of amultilayered printed wiring board modified from the one shown in FIGS. 1and 2. FIG. 4 is a cross sectional view showing the structure of anothermultilayered printed wiring board modified from the one shown in FIGS. 1and 2.

As shown in FIGS. 1 and 2, the multilayered printed wiring board 100includes a rigid wiring board 1 with wiring layers on both main surfacesthereof, a flexible wiring board 2 with wiring layers on both mainsurfaces thereof and another rigid wiring board 3. The rigid wiringboards 1, 3 and the flexible wiring board 2 are combined with oneanother to constitute a prescribed module board. The bottom side of themultilayered printed wiring board 100 is made of the flexible board 2entirely. The rigid boards 1 and 3 are disposed on the top surface ofthe flexible wiring board 2 in the long direction thereof with separatedfrom one another. A rigid insulating layer 14 is formed between theflexible wiring board 1 and the rigid wiring board 1 and between theflexible wiring board 1 and the rigid wiring board 3. Anelectric/electronic component 4 is embedded in the rigid wiring board 1.Hereinafter, the “electric/electronic component” may be called as a“part”.

The length of the flexible wiring board 2 is set larger than the lengthsof the rigid wiring boards 1 and 3. As shown in FIG. 1, therefore, therigid wiring boards 1 and 3 are disposed at both ends of the flexiblewiring board 2 so that the multilayered printed wiring board 100 ispartially constituted of the flexible wiring board 2. In this point ofview, the multilayered printed wiring board 100 can exhibit the hardnessdue to the rigid wiring boards 1 and 3 and the flexibility due to theflexible wiring board 2.

Since the widths of the rigid wiring boards 1 and 3 is set equal to thewidth of the flexible wiring board 2, the bottom surface of themultilayered printed wiring board 100 can be substantially flattened. Asdescribed above, since the multilayered printed wiring board 100 ispartially constituted of the flexible wiring board 2, the flexiblewiring board 2 is partially exposed. The exposed portion of the flexiblewiring board 2 may be slightly shortened in width in comparison with therigid wiring boards 1 and 3. The thickness of the rigid wiring board 1is set substantially equal to the thickness of the rigid wiring board 3.Therefore, the top surface of the multilayered printed wiring board 100is substantially flattened except the exposed flexible wiring board 2.

The outermost wiring patterns are partially exposed from both mainsurfaces of the multilayered printed wiring board 100 to constitute theexternal terminals for packaging. The remnants of the outermost wiringpatterns are covered with protective layers 6, e.g., made of solderresist. One or more electric/electronic components are electricallymounted on the external terminals. In this point of view, the externalterminals function as lands for mounting the electric/electroniccomponent(s). Since the top surface and the bottom surface of themultilayered printed wiring board are flattened, the electric/electroniccomponent(s) can be easily mounted on the multilayered printed wiringboard without any disturbance due to the convex portions of the topsurface and the bottom surface thereof. Herein, the surface patterningstructure is exemplified in this embodiment, and thus, not restricted tothe exemplified one. Moreover, the rigid wiring boards 1 and 3 areconstituted as a four-layered structure, but may be as another layeredstructure. For example, the rigid wiring boards 1 and 3 may beconstituted as an eight-layered structure as shown in FIG. 4.

Although the concrete size of the multilayered printed wiring board 100is not limited, the concrete size may be set almost equal to the size ofa normal module board to be housed into a portable device.

As shown in FIG. 3, the multilayered printed wiring board 100 may beconstituted so as not to contain the rigid wiring board 3. In this case,the right edge of the flexible wiring board 2 may be used as aconnection terminal for another component or board. Moreover, the partmay be embedded in the rigid wiring board 3. Since the rigid wiringboard 3 may be constructed in the same manner as the rigid wiring board1, the explanation for the rigid wiring board 3 may be omitted.

As the part 4 to be embedded may be exemplified a passive component suchas a chip resistor, a chip conductor, a chip inductance and an activecomponent such as a bare chip to be flip chip-bonded. The size of thepart 4 may be set to 0.4 mm×0.2 mm (0402) or 0.6 mm×0.3 mm (0603). Sincethe thickness of the exemplified part is almost equal to the narrow sideof the part, the exemplified part can be embedded into the rigid wiringboard with a thickness of about 0.5 mm.

As shown in FIGS. 1 to 4, in the multilayered printed wiring board 100of this embodiment, the part 4 is disposed in the rigid wiring board 1so as to be opposite to the lands for packaging as portions of the innerwiring layer 22. The electrode terminals 4 a of the part 4 areelectrically connected with the lands of the wiring layer 22 via theconnection 51. In this way, the part 4 can be embedded in the rigidwiring board 1. In this case, the part 4 is faced against the flexiblewiring board 2.

The connection 51 is made of solder cream, e.g., with a melting point of200 to 240° C. higher than a melting point of a normal solder to be usedin the packaging and connection for another electronic component. Inthis case, the connection 51 can not be re-melted in the packaging andconnection for another electronic component.

As shown in FIG. 2, an insulating layer 11 is formed in plane outsidefrom the wiring layer 22 so as to form a base for mounting the part 4via the wiring layer 22. The insulating layer 11 is formed in advancebefore the part 4 is mounted. In this point of view, the insulatinglayer 11 may be called as a “first rigid board”. The part 4 issurrounded by insulating layers 12 and 13. In other words, the part 4 isembedded in the insulating layers 12 and 13. The insulating layer 13constitutes a rigid board so that a predetermined area of the insulatinglayer 13 is removed in accordance with the position, the size and theouter shape of the part 4. In this point of view, the part 4 is disposedin the removed area, that is, the roll off 13 a of the insulating layer13. As a result, the insulating layer 13 functions as a second rigidboard for embedding the part 4 therein.

The insulating layers 11 to 14 may be made from the respective prepregs.Each prepreg may be made of a base of glass fiber nonwoven material,organic fiber nonwoven material or paper and an unhardened epoxy resin,polyimide resin, bismaleimide resin or phenol resin which is infiltratedinto the base. Concretely, glass cloth-epoxy based prepreg may beexemplified. Since the insulating layer 15 is flexible, the insulatinglayer 15 is made from a flexible prepreg for a flexible board. Theflexible prepreg is made of a base of glass cloth or the like and aresin such as polyimide resin flexible even after hardening.

The thickness of each insulating layer may be set within a range of 5.0to 120 μm when the thickness of the part 4 is set to about 0.2 mm. Thethickness of each insulating layer may be set within a range of 80 to160 μm when the thickness of the part 4 is set to about 0.3 mm. However,the thickness of each insulating layer may be set within a given rangein view of the thickness of the part 4. In this case, the thickness ofthe prepreg corresponding to the insulating layer is set within athickness range similar to the thickness range of the insulating layer.Therefore, the thickness of the prepregs of the insulating layers 12 and13 may be set larger than another prepreg of another insulating layer inorder to embed the part 4 in the insulating layers 12 and 13 withoutfail.

The insulating layers 12 and 14 may be made from prepregs with resin ofhigher fluidity therein at a temperature range to be required inmolding. In this case, the part 4 can be absolutely surrounded by theinsulating layers 12 and 14. The thickness of the flexible insulatinglayer 15 may be preferably set within a range of 20 to 60 μm. Too thinthickness may deteriorate the insulating property and the mechanicalstrength of the insulating layer 15. Too thick thickness may deterioratethe flexibility of the insulating layer 15. As shown in FIG. 4, theinsulating layer 11 and 13 may be constituted as multilayered insulatinglayers, respectively from the corresponding prepregs.

As described above, the insulating layer 12 is formed between theinsulating layers 11 and 13 so as to embed the space (containing theroll off 13 a of the insulating layer 13) around the part 4. Therefore,the shape of the insulating layer 12 around the part 4 becomescomplicated commensurate with the outer shape of the part 4. Theinsulating layer 12 can embed the space around the part 4 by the meltedresin of the corresponding prepreg at the formation of the insulatinglayer 12. In this case, the insulating layer 12 embeds the spaces of thewiring layers 21 and 22.

In this point of view, the shape of the insulating layer 12 may bechanged in accordance with the sizes, shapes and positions of the part 4and the wiring layers 21, 22. In this embodiment, the insulating layer12 is formed so as to cover the top surface of the part 4 and/or thebottom surface of the part 4 (refer to FIG. 2), but may be formed asoccasion demands. As shown in FIG. 3, the insulating layer 12 may beformed so as to cover the connection 51. In this case, the part 4 issurrounded by the insulating layers 12 and 14 so as to be embeddedbetween the rigid insulating layer 11 and the flexible wiring board 2.

In FIG. 3, the insulating layer 14 is infiltrated into the roll off 13 aso as to cover the top surface of the part 4. In other words, the part 4is surrounded and sealed by the insulating layers 12 and 14. As aresult, the part 4 is absolutely embedded into and protected by therigid insulating layers.

According to the multilayered printed wiring board 100 shown in FIG. 3,the total thickness of the board 100 can be reduced in comparison withthe thickness of the part 4. In FIG. 3, the rigid wiring board 3 isremoved, but may be provided at the right edge thereof in the samemanner as the board 100 in FIGS. 1 and 2.

In FIG. 4, since the insulating layer 13 is constituted as themultilayered structure using the corresponding prepregs, the part 4 canbe embedded in the insulating layer 13 even though the thickness of thepart 4 is large. In this case, since the thickness of each prepreg canbe set to a normal thickness range, the interlayer connection can beabsolutely formed through the corresponding prepregs by means ofconductive bump. Moreover, since the number of wiring layer can beincreased commensurate with the number of constituent insulating layer,the wiring can be freely designed so that the planer size of themultilayered printed wiring board 100 can be reduced.

In FIG. 4, the number of constituent insulating layer of the insulatinglayer 11 is set equal to the number of constituent insulating layer ofthe insulating layer 13, but may be different one another. In FIG. 4,the number of constituent insulating layer is set to three for theinsulating layers 11 and 13. The insulating layer 11 may be made of asingle layered structure, and the insulating layer 13 may be made of athree-layered structure. It is not required that the total thickness ofthe prepregs of the insulating layer 11 is set equal to the totalthickness of the prepregs of the insulating layer 13. If the totalthickness of the prepregs is set equal to one another, the warpage ofthe multilayered printed wiring board 100 can be prevented effectivelyafter the formation by means of pressing.

In the case that the insulating layers 12 and 14 are constituted as themultilayered structure, the insulating layers 12 and 14 may bestructured as shown in FIG. 2 or 4. In FIG. 2, the top surface of thepart 4 is covered with the insulating layer 12. In other words, theinsulating layers 12 and 14 may be formed as designed only if the part 4is surrounded by the insulating layers 12 and 14 and the connection 51is protected by the insulating layer 12. In fact, the part 4 issurrounded by the resins of the prepregs of the insulating layers 12 and14.

The interlayer connection conductors 31 to 35 are originated from theconductive bumps formed by means of screen printing of conductivecomposition paste (often called as “conductive paste”). Therefore, thediameter of each interlayer connection conductor is changed along theaxial direction thereof (the thickness direction of the board 100). Theconductive paste may be made, e.g., by dispersing conductive metallicpowders of Ag, Au or Cu into the resin paste. In the use of theconductive paste, the aspect ratio of the conductive bump can beincreased by means of screen printing using a metallic mask with alarger thickness. The diameter and height of the conductive bump may bedetermined in view of the wiring distance and the thickness of theprepreg.

The interlayer connection conductor 32 is disposed between the wiringlayers 22 and 23 so as to electrically connect the wiring layers 22 and23 through the insulating layer 12. The diameter of the interlayerconnection conductor 32 is increased from the top in the side of thewiring layer 22 to the bottom in the side of the wiring layer 23 becausethe conductive bump to be the interlayer connection conductor 32 isformed on the lands of the wiring layer 23 (see, FIGS. 2 to 4).

In this case, the interlayer connection conductor 32 can be formedeffectively and efficiently because the simultaneous screen printing ofthe solder cream for the packaging of the part 4 and the conductive paston the same surface of the wiring layer 22 requires a complicated screenprinting machine so that the manufacturing cost is increased.

The interlayer connection conductor 34 is disposed between the wiringlayers 24 and 25 so as to electrically connect the wiring layers 24 and25 through the insulating layer 14. The diameter of the interlayerconnection conductor 34 is increased from the top in the side of thewiring layer 24 to the bottom in the side of the wiring layer 25 becausethe conductive bump to be the interlayer connection conductor 34 isformed on the lands of the wiring layer 25 (see, FIGS. 2 to 4). In thiscase, since the forefront of the conductive bump to be the interlayerconnection conductor 34 is pressed against the rigid insulating layer13, the interlayer connection conductor 34 can be connected with thewiring layer 24 without fail.

The interlayer connection conductors 31, 33 and 35, which are formedthrough the insulating layer 11 (first rigid board), the insulatinglayer 13 (second rigid board) and the insulating layer 15 (flexibleboard), may be configured as occasion demands. It is desired, however,to decrease the diameter of each interlayer connection conductor in theside for a smaller wiring pattern to be formed. In this point of view,the diameter of each interlayer connection conductor is decreased alongthe axial direction from the bottom to the top of the multilayeredprinted wiring board 100. The interlayer connection conductor 31 toelectrically connect the wiring layers 21 and 22 which are formed onboth main surfaces of the insulating layer 11 may be made of aconductive film formed in a through-hole, not from a conductive bump.The interlayer connection conductors 33 and 35 may be formed in the samemanner as the interlayer connection conductor 31. The interlayerconnection conductor 33 electrically connects the wiring layers 23 and24 formed on both main surfaces of the insulating layer 13. Theinterlayer connection conductor 35 electrically connects the wiringlayers 25 and 26 formed on both main surfaces of the insulating layer15.

In this embodiment, since the part 4 such as the 0402 chip is embeddedinto the multilayered printed wiring board 100, the multilayered printedwiring board 100 can be downsized without the decrease of the number ofpart. Then, since the multilayered printed wiring board 100 includes therigid wiring board 1, the multilayered printed wiring board 100 canmaintain the desired hardness. Then, since the multilayered printedwiring board 100 partially includes only the flexible wiring board 2,the multilayered printed wiring board 100 can maintain the desiredflexibility. In this embodiment, since the part 4 is embedded in therigid wiring board 1, the part 4 can be protected against externalmechanical shock.

In this embodiment, the multilayered printed wiring board 100 isconfigured such that some parts can be mounted on the flexible wiringboard 2 (the bottom surface) in addition to on the rigid wiring board 1(the top surface).

In this point of view, if the multilayered printed wiring board 100 isconfigured as a normal size, many parts can be contained for themultilayered printed wiring board 100 because one or more parts can beembedded in the multilayered printed wiring board 100 (insulatinglayers) and one or more parts can be mounted on both surfaces of themultilayered printed wiring board 100. If the number of part is set to aconventional one, the multilayered printed wiring board 100 can bedownsized in comparison with a conventional one.

Therefore, the multilayered printed wiring board 100 may be employed asa module board to be used for a sensor module or a camera module. Sincethe module board is built in a portable device, the module board isrequired to be downsized, thinned, grown in density and also, flexibleenough to be bended and housed at the fabrication of the portabledevice.

(Manufacturing Method)

Some embodiments related to the manufacturing method of the multilayeredprinted wiring board will be described with reference to FIGS. 5 to 16.As described previously, like or corresponding components are designatedby the same reference numerals throughout the drawings.

As shown in FIG. 5, first of all, the first rigid wiring board structure10 is prepared. The part 4 is embedded in the structure 10. Then, thesecond rigid wiring board structure 20 is prepared. The roll off 43 isformed at the second rigid wiring board structure 20 and the interlayerconnection conductor 32 is formed through the prepreg 12A. Then, theflexible wiring board structure 2B is prepared. The structure 2Bcontains the flexible wiring board 2 and the interlayer connectionconductor 32 through the prepreg 12A. The first rigid wiring boardstructure 10, the second rigid wiring board structure 20 and theflexible wiring board structure 2B are positioned and pressed oneanother. Then, the formation process of each structure will be describedhereinafter.

(Formation of Rigid Wiring Board Structure) (Preparation of Rigid Boardfor Part to be Embedded)

FIG. 6 relates to cross sectional views schematically showing some stepsfor forming the rigid wiring board structure 10. First of all, as shownin FIG. 6( a), the conical conductive bumps are formed by means ofscreen printing using conductive paste on the conductive foil(electrolytic copper foil) 22A. The conductive bumps are converted intothe interlayer connection conductors 31. The bottom diameter of theconductive bump may be set to 200 μm and the height of the conductivebump may be set to 160 μm. The conductive bumps are dried and hardenedso as to be converted into the interlayer connection conductors 31.

Then, as shown in FIG. 6( b), the prepreg 11A is formed on the samesurface of the conductive foil 22A and pressed so that the forefronts ofthe interlayer connection conductors 31 are exposed through the prepreg11A. The forefronts of the interlayer connection conductors 31 may bepressed and flattened during or after the formation of the interlayerconnection conductors 31. The diameter of the interlayer connectionconductor 31 is changed along the axial direction. Then, as shown inFIG. 6( c), the conductive foil (electrolytic copper foil) 21A is formedon the prepreg 11A and pressed against the prepreg 11A. In this case,the conductive foil 21A is electrically connected with the interlayerconnection conductors 31 and the prepreg 11A is hardened to be theinsulating layer 11. The interlayer connection conductors 31 are formedin conical trapezoidal shape because the forefronts of the interlayerconductors 31 are flattened.

Then, as shown in FIG. 6( d), the conductive foil 22A is patterned bymeans of photolithography so as to form the wiring pattern 22 containingthe lands for packaging and for connection. The packaging lands are usedfor mounting the part 4 and the connection lands are used for connectingthe forefronts of the interlayer connection conductors 32 as shown inFIGS. 2 and 3. As shown in FIG. 6( e), the solder cream 51A is printedon the packaging land by means of screen printing. The solder cream 51Acan be easily printed by means of screen printing. Instead of the screenprinting technique, a dispenser may be employed. Instead of the soldercream 51A, a conductive resin may be employed.

Then, the part 4 is mounted on the packaging lands via the solder cream51A by means of mounter. The solder cream 51A is ref lowed in a reflowfurnace. As a result, as shown in FIG. 6( f), the part 4 can be mountedon the packaging lands of the wiring layer 22 via the connection 51,thereby completing the wiring board structure 10A. The wiring boardstructure 10A will be employed in the subsequent process as shown inFIG. 8.

(Preparation of Rigid Board Containing Space to Embed Part)

FIG. 7A relates to cross sectional views schematically showing somesteps for forming the rigid board containing the space to embed thepart. First of all, as shown in FIG. 7A(a), the conductive foils(electrolytic copper foils) 23A and 24A are formed in a given thicknesson both main surfaces of the rigid insulating layer 13 so as to beelectrically connected with one another via the interlayer connectionconductor 33 formed through the insulating layer 13. As a result, therigid board with the conductive foils formed on both main surfacesthereof can be formed. The process in FIG. 7A(a) is similar to theprocess in FIGS. 6( a) to (c).

Then, as shown in FIG. 7A(b), the conductive foil 23A (to be opposite tothe insulating layer 11) is patterned by means of photolithography toform the wiring layer (wiring pattern) 23 containing the lands forconnection. The connection lands are employed for forming the interlayerconnection conductors 32 as shown in FIGS. 2 and 3. In this case, thebottoms of the interlayer connection conductors 32 with a largerdiameter are positioned on the lands.

Then, the conductive bumps are formed in conical shape (e.g., the bottomdiameter: 200 μm, the height: 160 μm) on the connection lands 23 bymeans of screen printing using the conductive paste. The conductivebumps are dried and hardened to be converted into the interlayerconnection conductor 32.

Then, as shown in FIG. 7A(d), the prepreg 12A under semi-hardenedcondition is formed on the wiring layer 23 by means of pressing machine.In this case, the forefronts of the interlayer connection conductors 32are exposed from the prepreg 12A. The forefronts of the interlayerconnection conductors 32 may be flattened during or after the formationof the interlayer connection conductors 32. The interlayer connectionconductors 32 are configured such that each diameter is changed alongthe axial direction. In this case, the wiring layer 23 is embedded bythe prepreg 12A.

Then as shown in FIG. 7A(e), the roll off 13 a is formed for disposingthe part 4 therein. The roll off 13 a may be formed as a through-hole 43at the laminated structure as shown in FIG. 7( d). The roll off 13 a maybe formed by means of normal processing means such as drilling, routerprocessing, punching processing or laser processing. The size of theroll off 13 a may be determined commensurate with the size of the part4. In the processing of the roll off 13 a, it is desired not to createpowder dust in view of the subsequent embedding of the part 4. It isdesired, therefore, to remove the powder dust by means of dust roller,air blow machine or dust collector after the through-hole 43, that is,the roll off 13 a is formed. If a protective layer is formed on theprepreg 12A so as to cover the forefronts of the interlayer connectionconductors 32, the powder dust is unlikely to be directly attached tothe forefronts of the interlayer connection conductors 32 and theprepreg 12A. In this way, the wiring board structure 20A can be formed.

As shown in FIG. 6, the part 4 can be mounted on any lands within theallowable range of the wiring layer 22. As shown in FIG. 7, in contrast,the roll off 13 a is necessarily formed in view of the size, the shapeand the position of the part 4.

FIG. 7B relates to cross sectional views schematically showing someother steps for forming the rigid board containing the space to embedthe part. The steps shown in FIG. 7B correspond to the steps modifiedfrom the ones in FIG. 7A. The steps shown in FIGS. 7B(a) and (b) aresimilar to the steps shown in FIGS. 7A(a) and (b). Therefore, theinterlayer connection conductors 33 are formed through the insulatinglayer 13, and the conductive foil 24A is formed on the rear surface ofthe insulating layer 13, and the patterned wiring layer 23 is formed onthe main surface of the insulating layer 13. Then, the roll off 13 a isformed as the through-hole 43 through the wiring layer 23, theinsulating layer 13 and the conductive foil 24A. Then, as shown in FIG.7B(d), the conical conductive bumps are formed by means of screenprinting using the conductive paste. In this case, since thethrough-hole 43 (roll off 13 a) is formed in advance, the insulatinglayer 13 may be warped by the screen printing. In this point of view, itis desired that the roll off 13 a is embedded with the jig 61. Herein,it is required that the jig 61 is not projected from the insulatinglayer 13 and the conductive foil 24A so as to maintain flat the mainsurfaces of the laminated structure shown in FIG. 7B(d).

Then, as shown in FIG. 7B(e), the jig 61 for the screen printing isremoved, and the prepreg 12A under semi-hardened condition (B-stage) isformed on the insulating layer 13 so as to cover the wiring layer 23 sothat the position of the roll off 13 a (through-hole 43) of the prepreg12A can be matched with the roll off 13 a (through-hole 43) of thelaminated structure. As a result, the wiring board structure 20A can beformed. According to the steps shown in FIG. 7B, since the interlayerconnection conductors 32 are formed after the through-hole 43 is formed,the powder dust created at the formation of the through-hole 43 can beremoved before the interlayer connection conductors 32 are formed. Inthis case, the interlayer connection conductors 32 can be formed underno powder dust condition.

The interlayer connection conductors 33 may be made of the conductivefilms formed on the inner walls of the through-holes or the conductivecomposition materials filled in the through-holes. For example, if thethickness of the insulting layer 13 is increased, the sizes of theinterlayer connection conductors, particularly, the heights anddiameters of the bottom surfaces of the interlayer connection conductorsmay be also increased. Therefore, the formation of the interlayerconnection conductors may disturb the miniaturization of the wiringlayer(s), that is, the intended multilayered printed wiring board 100.In this point of view, when the insulating layer is formed thick, theinterlayer connection conductors are preferably made of the conductivefilms or the conductive composition materials which are formed in thethrough-hole through the insulating layer. In this case, the diameter ofthe interlayer connection conductor becomes uniform along the axialdirection. Herein, the interlayer connection conductors may be formed inany shape only if the interlayer connection conductors can electricallyconnect the adjacent wiring layers.

(Rigid Wiring Board: Combination Through Laminating)

FIG. 8 shows the arrangement between the wiring board structure 10A andthe wiring board structure 20A. The wiring board structure 10A islaminated onto the wiring board structure 20A and pressed under heatingcondition so that the part 4 can be inserted into the roll off 13 a(through-hole 43) and the forefronts of the interlayer connectionconductors 32 can be electrically contacted with the lands of the wiringlayer 22. The pressing may be carried out for both sides of the thuslaminated structure. In this case, the prepreg 12A is perfectly hardenedso that the wiring board structure 10A is combined with the wiring boardstructure 20A via the prepreg 12A.

In this case, since the prepreg 12A is rendered fluid through theheating, the prepreg 12A is partially infiltrated around the part 4 sothat the part 4 can be sealed with the resin of the prepreg 12A. In thiscase, the connection 51 is also covered with the resin of the prepreg12A. Since the part 4 is sealed with the resin of the prepreg 12A, thepart 4 is also fixed with the resin of the prepreg 12A. Therefore, thepart 4 can be electrically connected with the lands of the wiring layer22 without fail. In the case that the part 4 is mounted on the board,since the part 4 is very small so that the connection between the part 4and the electrode terminals is also very small, the part 4 is likely tobe dropped out of the electrode terminals due to the soldering reflow.In contrast, in this embodiment, the part 4 can be fixed in the boardwith the resin of the prepreg without fail so that the reliability ofthe part 4 can be improved.

Then, as shown in FIG. 9, the conductive foils 21A and 24A are patternedby means of photolithography to form the wiring layers 21 and 24. Thewiring layer 24 includes the lands for connecting the forefronts of theinterlayer connection conductors 34 shown in FIG. 2. Then, theprotective layer 6, e.g., made of solder resist, is formed on the wiringlayer 21 so as to expose the portions of the wiring layer 21 to be usedas external terminals. No protective layer is formed on the wiring layer24 to which the flexible wiring board is to be formed. In this way, theintended rigid wiring board 1 containing the part 4 therein can beformed as shown in FIG. 9.

In FIGS. 6 to 8, the patterning process of the wiring layers 21 and 24and the forming process of the protective layer 6 are carried out afterthe wiring board structures 10A and 20A are laminated and combined oneanother via the prepreg 12A. As shown in FIG. 10, however, thepatterning process of the wiring layers 21 and 24 and the formingprocess of the protective layer 6 are carried out before the wiringboard structures 10A and 20A are laminated and combined one another viathe prepreg 12A. Both processes relating to FIGS. 6 to 8 and FIG. 10 maybe employed only if the wiring layers 21 and 24 are patterned before theflexible wiring board is laminated via the wiring layers 21 and 24. Someportions of the patterned wiring layer 24 function as the lands forelectrically connecting the interlayer connection conductors 34.

In the embodiment relating to FIG. 10, the patterning process of thewiring layer 24 is not required after the part 4 is inserted into theroll off 13 a so that the part 4 may be projected from the insulatinglayer 12 or uncovered with the resin of the prepreg 12A.

(Preparation of Flexible Wiring Board)

Then, the manufacturing process of the flexible wiring board 2 to belaminated on the rigid wiring board 1 will be described with referenceto FIG. 11.

First of all, as shown in FIG. 11( a), the conical conductive bumps areformed by means of screen printing using conductive paste on theconductive foil (electrolytic copper foil) 25A. The conductive bumps areconverted into the interlayer connection conductors 35. The bottomdiameter of the conductive bump may be set to 200 μm and the height ofthe conductive bump may be set to 160 μm. The conductive bumps are driedand hardened so as to be converted into the interlayer connectionconductors 35.

Then, as shown in FIG. 11( b), the prepreg 15A under semi-hardenedcondition (B stage) is formed on the same surface of the conductive foil25A and pressed so that the forefronts of the interlayer connectionconductors 35 are exposed through the prepreg 15A. The forefronts of theinterlayer connection conductors 35 may be pressed and flattened duringor after the formation of the interlayer connection conductors 35. Then,as shown in FIG. 11( c), the conductive foil (electrolytic copper foil)26A. e.g., with a thickness of about 18 μm is formed on the prepreg 15Aand pressed against the prepreg 15A. In this case, the conductive foil26A is electrically connected with the interlayer connection conductors35 and the prepreg 15A is hardened to be the flexible insulating layer15. The interlayer connection conductors 35 are formed in conicaltrapezoidal shape because the forefronts of the interlayer connectionconductors 35, are flattened. The diameters of the interlayer connectionconductors 35 are changed along the axial direction and the stackingdirection of the foils and the prepregs.

Then, as shown in FIG. 11( d), the conductive foils 25A and 26A arepatterned by means of photolithography so as to form the wiring patterns25 and 26. The wiring pattern 25 is located inside in the multilayeredprinted wiring board 100 so as to contain the lands for connection. Theconnection lands of the wiring pattern 25 are formed so as to correspondto the connection lands of the bottom wiring layer 24 of the rigidwiring board 1. The wiring pattern 26 contains the terminals 5 forpackaging. Then, the protective layer 6, e.g., made of solder resist, isformed on the wiring patterns 25 and 26 except the connection lands andthe external terminals. In this way, the two-sided flexible wiring board2 is formed.

Then, as shown in FIG. 11( e), the conductive bumps 34A to be theinterlayer connection conductors 34 are formed in conical shape (e.g.,the bottom diameter: 200 μm, the height: 160 μm) on the connection landsof the wiring layer 25 by means of screen printing using the conductivepaste. The conductive bumps 34A are dried and hardened to be convertedinto the interlayer connection conductors 34.

Then, as shown in FIG. 11( f), the prepreg 14A under semi-hardenedcondition is formed on the wiring layer 25 by means of pressing machine.Not shown, the prepreg 14A is also formed on the side of the wiringlayer 25 on which the rigid wiring board 3 is laminated. Thethrough-hole 43 to house the part 4 may be formed for the prepreg 14A inadvance in the same manner as the insulating layer 13 (refer to FIG.13). In this case, the part 4 can not be stressed by the glass cloth orthe like contained in the prepreg 14A even though the distance betweenthe top surface of the part 4 to be embedded and the wiring layer 25 ofthe flexible wiring board 2 is decreased.

In this case, the forefronts of the interlayer connection conductors 34are exposed from the prepreg 14A. The forefronts of the interlayerconnection conductors 34 may be flattened during or after the formationof the interlayer connection conductors 34. The interlayer connectionconductors 34 are configured such that each diameter is changed alongthe axial direction. In this case, the wiring layer 25 is embedded bythe prepreg 14A.

The two-sided flexible wiring board with the interlayer connectionconductors through the insulating layer and the prepreg is called as thewiring board structure 2B for convenience. Herein, the two-sidedflexible wiring board may be formed by another manufacturing process.Moreover, the flexible wiring board may be configured as anotherstructured wiring board. For example, the flexible wiring board may bemade of polyimide or by means of interlayer connection using thethrough-hole. In this case, the steps shown in FIGS. 11( e) and (f),that is, the formation of the prepreg 14A and the formation of theconductive bumps through the prepreg 14A are required.

(Combination of Rigid Wiring Board and Flexible Wiring Board)

As shown in FIG. 12, the rigid wiring board 1 obtained in FIG. 9 islaminated onto and pressed against the wiring board structure 2B underheating condition so that the forefront of the interlayer connectionconductors 34 can be opposite to the connection lands of the wiringlayer 24. In the wiring board structure 2B, as described above, theforefronts of the interlayer connection conductors 34 are exposed fromthe prepreg 14A. The pressing may be carried out for both sides of thethus laminated structure. In this case, the prepreg 14A is perfectlyhardened so that the rigid wiring board 1 is combined with the wiringboard structure 2B via the prepreg 14A.

In this case, the forefronts of the interlayer connection conductors 34are plastically deformed and flattened against the connection lands ofthe wiring layer 24 of the rigid wiring board 1 so that the wiring layer24 can be electrically connected with the interlayer connectionconductor 34. The interlayer connection conductors 34 are formed inconical trapezoidal shape so that each diameter can be changed along theaxial direction. In this embodiment, the diameter of each interlayerconnection conductor 34 is increased from the side of the wiring layer24 to the side of the wiring layer 25. In this way, the intendedmultilayered printed wiring board 100 can be obtained as shown in FIGS.1 and 2.

FIGS. 14 to 16 relate to cross sectional views schematically showingsome steps in a manufacturing method for the multilayered printed wiringboard in FIG. 4.

As shown in FIG. 14, the first rigid board and the second rigid boardare prepared, respectively. The first rigid board is configured as afour-layered wiring board containing rigid three insulating layers andas mounting the part. The second rigid board is also configured as afour-layered wiring board containing rigid three insulating layers andas providing a space for the part to be embedded. The first rigid boardand the second rigid board can be formed in the same manner as shown inFIGS. 6 to 9.

Then, as shown in FIG. 14, the part 4 is mounted on the lands of thewiring layer 22 and the electrode terminals 4 a are electricallyconnected with the wiring layer 22 via the connection 51, therebyforming the first rigid wiring board structure 10 in the same manner asshown in FIGS. 6( d) and (f). Then, the conductive bumps as theinterlayer connection conductors 32 are formed on the wiring layer 23formed on the main surface of the insulating layer 13, and the prepreg12A under semi-hardened condition is formed on the same surface so thatthe forefronts of the interlayer connection conductors 32 are exposedfrom the prepreg 12A. Then, the through-hole 43 is formed at the thusobtained laminated structure so as for the part 4 to be embedded. Inthis way, the second rigid wiring board structure 20 can be formed(refer to FIGS. 7A and 7B). The forefronts of the interlayer connectionconductors 32 may be flattened during or after the exposure of theforefronts thereof from the prepreg 12A.

Then, the first rigid wiring board structure 10 is positioned for andpressed under the heating condition against the second rigid wiringboard structure 20. The pressing may be carried out by means of pressingmachine. In this case, the first rigid wiring board structure 10 iscombined with the second rigid wiring board structure 20, therebyforming the rigid wiring board 1 as shown in FIG. 15. The interlayerconnection conductors 32 are configured such that the diameter of eachinterlayer connection conductor is changed along the axial direction. InFIG. 15, the diameter of each interlayer connection conductor isincreased from the side of the wiring layer 22 to the side of the wiringlayer 23. Then, as shown in FIG. 16, the rigid wiring board 1 ispositioned for and pressed against the flexible wiring board 2, therebyforming the multilayered printed wiring board 100 as shown in FIG. 4.

As described above, according to the manufacturing methods of theseembodiments, one rigid board with the part to be embedded is laminatedonto and pressed against the other rigid board. In this case, since theroll off is formed at the other rigid board commensurate with the part,the part can be inserted into the roll off at the laminating and thepressing. In this way, the intended rigid wiring board is formed andpressed against the flexible wiring board, thereby forming themultilayered printed wiring board which can exhibit the hardness and theflexibility and contain the part therein.

Since the part is mounted on the main surface of the rigid board, themounting operation of the part can be easily carried out by means of anormal mounter. Then, since the rigid board is laminated onto theadditional rigid board so that the part can be inserted into the rolloff of the additional rigid board, the part can not be stressed by theadditional rigid board. Also, since the prepreg is employed, the partcan be sealed with the resin of the prepreg without an additionalsealing member. Since the part can be embedded at the laminating andpressing, the manufacturing process of the multilayered printed wiringboard can be simplified.

In these embodiments, since the interlayer connection conductors aremade from the conductive bumps, the multilayered printed wiring boardcan be grown in density and the manufacturing process can be simplified.Since the part is mounted on the lands of the wiring layer, theelectrical connection of the part can be checked before the packaging(embedding). In this point of view, the yield ratio of the multilayeredprinted wiring board can be developed so that the manufacturing processof the multilayered printed wiring board can be simplified. The rigidboard and the flexible board can be made from normal materials,respectively so that the manufacturing cost of the multilayered printedwiring board can be reduced.

Since the part 4 is inserted into the roll off 13 a formed by partiallyremoving the prepregs to be the insulating layers 12 and 13, the part 4can not be stressed by the reinforcement member such as glass fiber soas to be protected appropriately. Since the part 4 is filled with theresin of the prepreg, the part 4 can be operated without fail under noglass fiber and powder dust.

In other words, since the part 4 is filled with the resin of theprepregs to be the insulating layers 12 and 14, the part 4 is notstressed by the glass fiber or the aramid fiber as the reinforcementfiber, and thus, appropriately protected. Moreover, since at least onehard insulating layer made of a prepreg reinforced by the glass fiber orthe like is located in the vicinity of the part 4, the part 4 can beprotected by external pressure and bending.

In these embodiment, when the rigid wiring board 1 is combined with theflexible wiring board 2 via the prepreg 14A, the conductive bumps 34A asthe interlayer connection conductors 34 are formed on the flexiblewiring board 2, not on the rigid wiring board 1 as described above withreference to FIGS. 5 and 11. Namely, the bottoms of the conductive bumps34A are located on the flexible wiring board 2 and the tops of theconductive bumps 34A are faced for the rigid wiring board 1 as shown inFIGS. 2 to 4.

The interlayer connection conductors 34 is located between the wiringlayers 24 and 25. The wiring layer 24 is formed on the hard insulatinglayer 13 and the wiring layer 25 is formed on the flexible insulatinglayer 15. Therefore, the forefronts of the conductive bumps arecontacted with and deformed by the hard insulating layer 13 through thelaminating and pressing so that the diameter of the bottom of eachinterlayer connection conductor becomes large and the diameter of thetop of each interlayer connection conductor becomes small. In this case,the interlayer connection conductors 34 can be electrically connectedwith the wiring pattern 24 (connection lands 24) without fail. Moreover,since the bottoms of the interlayer connection conductors 34 areconnected with the flexible wiring board, the diameters of the bottomsof the interlayer connection conductors 34 being larger than thediameters of the tops of the interlayer connection conductors 34, theflexible wiring board can not be deformed by the electrical connectionof the interlayer connection conductors 34. In contrast, the interlayerconnection conductors 34 are electrically connected with the rigidwiring board through the plastic deformation of the forefronts of theinterlayer connection conductors 34. In this point of view, the rigidwiring board can be electrically connected with the flexible wiringboard without fail via the interlayer connection conductors 34.

The conductive bumps may be formed on the rigid wiring board, but inthis case, the above-described effect/function can not be exhibited.

In these embodiments, the part is mounted on the rigid board andembedded so that the manufacturing process can be simplified and themanufacturing reliability can be enhanced. In another case, the part maybe mounted on the flexible board. In this case, however, since thesolder cream and the conductive bumps are required to be formed on thesame surface of the flexible board, the screen printing machine must bedevised in order to realize the simultaneous formation of the soldercream and the conductive bumps so that the manufacturing process becomescomplicated. In order to avoid the disadvantage, the conductiveconnection bumps may be formed on the rigid board. In this case,however, since the forefronts of the conductive bumps are connected withthe flexible board, the flexible board may be plastically deformed whilethe forefronts of the conductive bumps are not plastically deformed. Asa result, the rigid wiring board 1 may not be electrically connectedwith the flexible wiring board 2 without fail via the interlayerconnection conductors 34.

Accordingly, the part is mounted on the first rigid board and theconductive bumps are formed on the flexible wiring board 2 so as toelectrically connect the rigid wiring board and the flexible wiringboard. Then, the second rigid board is prepared and the roll off toembed the part therein is formed at the second rigid board, and theconductive bumps are formed on the second rigid board so as toelectrically connect the first rigid board and the second rigid board.According to these embodiments, the multilayered printed wiring boardcan be downsized while the number of part to be mounted is notdecreased, and exhibit the hardness and flexibility simultaneously.Also, the reliability for the electrical connection of the multilayeredprinted wiring board can be enhanced.

Although the present invention was described in detail with reference tothe above examples, this invention is not limited to the abovedisclosure and every kind of variation and modification may be madewithout departing from the scope of the present invention.

1. A multilayered printed wiring board, comprising: a flexible wiringboard with wiring layers on both main surfaces thereof; a rigid wiringboard with wiring layers on both main surfaces thereof and formedopposite to said flexible wiring board under the condition that an areaof said main surface of said rigid wiring board is smaller than an areaof said main surface of said flexible wiring board; and anelectric/electronic component embedded in said rigid wiring board. 2.The multilayered printed wiring board as set forth in claim 1, furthercomprising: an insulating layer disposed between said flexible wiringboard and said rigid wiring board; and an interlayer connectionconductor formed along an axial direction thereof and disposed betweensaid flexible wiring board and said rigid wiring board through saidinsulating layer so as to electrically connect said flexible wiringboard and said rigid wiring board via said wiring layers formed on saidmain surfaces of said flexible wiring board and said rigid wiring board,wherein a diameter of said interlayer connection conductor in the sideof said rigid wiring board is set smaller than a diameter of saidinterlayer connection conductor in the side of said flexible wiringboard.
 3. The multilayered printed wiring board as set forth in claim 1,wherein said electric/electronic component is disposed on a first wiringlayer contained in said rigid wiring board so that saidelectric/electronic component can be electrically connected with saidwiring layer via an connection.
 4. The multilayered printed wiring boardas set forth in claim 3, wherein said rigid wiring board includes asecond wiring layer in the side of said flexible wiring board withrespect to said first wiring layer; and wherein another interlayerconnection conductor is disposed between said first wiring layer andsaid second wiring layer so as to electrically connect said first wiringlayer and said second wiring layer.
 5. A multilayered printed wiringboard, comprising: a flexible wiring board with wiring layers on bothmain surfaces thereof; a rigid wiring board with wiring layers on bothmain surfaces thereof and formed opposite to said flexible wiring boardvia an insulating layer; an interlayer connection conductor disposedthrough said insulating layer so as to electrically connect saidflexible wiring board and said rigid wiring board under the conditionthat a forefront of said interlayer connection conductor is plasticallydeformed through the connection for said rigid wiring board and a bottomof said interlayer connection conductor is connected with a connectionland of said wiring layer of said flexible wiring board; and anelectric/electronic component embedded in said rigid wiring board. 6.The multilayered printed wiring board as set forth in claim 5, whereinsaid rigid wiring board comprises: a first rigid board to mount saidelectric/electronic component on a main surface thereof; a second rigidboard disposed opposite to said main surface of said first rigid boardon which said electric/electronic component is mounted under thecondition that a roll off to house said electric/electronic component isformed as a through-hole at said second rigid board; an insulating layerdisposed between said first rigid board and said second rigid board andsurrounding said electric/electronic component so as to embed said rolloff; and an interlayer connection conductor disposed through saidinsulating layer under the condition that a diameter of said interlayerconnection conductor in the side of said first rigid board is setsmaller than a diameter of said interlayer connection conductor in theside of said second rigid board, wherein said second rigid board of saidrigid wiring board is connected with said flexible wiring board.
 7. Themultilayered printed wiring board as set forth in claim 5, wherein saidflexible wiring board is exposed on a main surface of said multilayeredprinted wiring board so that said main surface of said multilayeredprinted wiring board can be flattened and said flexible wiring board andsaid rigid wiring board are exposed on the other main surface of saidmultilayered printed wiring board.
 8. The multilayered printed wiringboard as set forth in claim 6, wherein said electric/electroniccomponent is embedded in a resin of a prepreg to be converted into saidinsulating layer.
 9. A method for manufacturing a multilayered printedwiring board, comprising the steps of: preparing a first rigid board anda second rigid board; mounting an electric/electronic component on amain surface of said first rigid board; forming a roll off to house saidelectric/electronic component at said second rigid board; laminatingsaid first rigid board and said second rigid board so that saidelectric/electronic component can be inserted in said roll off, therebyforming a rigid wiring board; and laminating said rigid wiring board anda flexible wiring board via a prepreg to be converted into an insulatinglayer so that said rigid wiring board can be electrically connected withsaid flexible wiring board via an interlayer connection conductor. 10.The manufacturing method as set forth in claim 9, wherein saidinterlayer connection conductor is made of a conductive bump by means ofscreen printing.